EP0129345A2

EP0129345A2 - Rotary fluid pump

Info

Publication number: EP0129345A2
Application number: EP84303430A
Authority: EP
Inventors: Manfred Sommer; Robert A. Gudheim
Original assignee: SINE PUMPS NV
Current assignee: CESSIONE;MANFRED AND URSULA SOMMER GBR
Priority date: 1983-05-21
Filing date: 1984-05-21
Publication date: 1984-12-27
Also published as: CA1224361A; EP0129345A3; DE3474051D1; JPH037034B2; ATE37214T1; US4575324A; JPS6045789A; EP0129345B1

Abstract

A rotary fluid pump has a pump housing or shell (21), an inlet (35) and outlet (36) and a pump chamber in which an undilating rotor (28) forms axially off set pockets with the chamber end surfaces (50.1, 50.2) for conveying pumped medium from inlet (35) to outlet (36) and moves a gate means (31) springingly bearing with rounded nose portions (73) on the rotor vane (30) to separate a suction chamber (25) and discharge chamber (27) connected to the inlet and outlet respectively. Improved separation of the suction and discharge chamber results by providing that the vane portion (30) has a thickness (T) which varies in a circumferential direction in differently inclined vane parts and varies in a radial direction in the inclined vane parts to provide line contact with the rounded nose portion (73) throughout the radial extent of the vane portion (30) during a full revolution of the rotor (28).

Description

The invention relates to a rotary fluid pump suitable for use, for example, in pumping media containing delicate components and thick material.

Background of the Invention

Ortmans German Patent 1123 (1877) disclosed a pump having a rotor rotating in a cylindrical pump chamber with planar end walls which rotor comprises a hub portion and an undulating vane portion, which extends radially of the hub and has an outer periphery in sliding engagement with the inner periphery of the pump chamber, and crests of undulations in sliding contact with opposite end walls of the pump chamber to form a plurality of pockets for transporting fluid from an inlet to an outlet which are separated from one another by a reciprocable gate member in sliding engagement with opposite faces of the vane portion of the rotor.
The rotor is mounted by glands in the housing and is of cast-iron with two spiral surfaces arranged symmetrically and of uniform thickness. The rotor contacts the pump housing. The reciprocable gate members pass through slots in the housing wall and engage, for sealing, the sides of the vane portion as well as its cylindrical outer face. The gate members may have individual spring bias.
Pumps of this type have not come into commercial use despite of the apparent advantage that no valving is required. It is believed that there are problems with Ortman pump which have not been solved or even recognised.
One unappreciated problem may have been that the barrier slider and disk in the Ortman pump do not "wear in" to increasingly conform and sealingly engage as wear takes place. Satisfactory sealing engagement may hence unexpectedly have to be provided from the outset, preferably in such a way that sealing engagement is little affected by wear whilst dismantling of the pump for maintenance of the sealing functions is unusually important.
The invention aims to improve pumps of this type to overcome the problems which heretofore have prevented such pumps from coming into use.

Summary of Invention

The invention provides an improved form of rotary fluid pump adapted, in a first aspect of the invention, to improve sealing and, in a second aspect of the invention to improve overall construction to facilitate dismantling maintenance and assembly.
According to the first aspect of the invention there is provided a pump having a rotary fluid pump having a hollow shell with two separable parts and means for securing the parts together, a pump chamber with a suction chamber, a discharge chamber and transport zone extending circumferentially between the suction chamber and the discharge chamber, a rotor rotatably received in the pump chamber with a hub portion and an undulating vane portion projecting radially outwards from the hub portion and having an outer periphery slidably engaging an inner peripheral surface of the transport zone of the pump chamber and opposite surfaces which in a circumferential direction are continuous cyclic curves with at least two complete cycles, crests of the curves slidably engaging opposite planar end surfaces of the pump chamber, gate means separating the suction and discharge chambers with rounded nose portions springingly engaging opposite faces of the vane member, and inlet and outlet openings communicating respectively with the suction and discharge chamber, improved by providing that the vane portion has a thickness which varies in a circumferential direction in differently inclined vane parts and varies in a radial direction in the inclined vane parts to provide line contact with the rounded nose portions throughout the radial extent of the vane portion during a full revolution of the rotor. By providing proper sealing with a rounded nose, the sealing engagement is not as easily affected by wear of the noses or rotor.
In accordance with the invention, the nose portions of the gate means are rounded with a predetermined radius of curvature and the opposite surfaces of the undulating vane portion of the rotor is designed as a function of the amplitude of the undulations (movement of the sliders), the number of undulations for revolution (at least two), the radius of the nose portions of the sliders and the radius of each incremental portion of the surface (distance from the axis of rotation) to maintain line contact. The position of the contact line will vary in the course of rotation as will be explained. Such surface can be produced by a computerized shaping or milling machine programmed to take these parameters into account. However, a practical and economical method of producing the rotor is to cast its approximate shape and then finish the vane portions of the rotor by means of a cylindrical milling cutter or other tool of the same radius as the nose portions of the slider. The cutter is mounted with its axis of rotation perpendicular to the axis of rotation of the rotor and, as the rotor is rotated, the cutter is reciprocated axially of the rotor in timed relation with the rotation of the rotor so as to make at least two complete strokes for each rotation of the rotor. By means of two cutters spaced apart a distance equal to the desired spacing of the nose portions of sliders forming the gate means, both surfaces of the vane can be machined simultaneously. Alternatively the two sides can be machined individually, care being taken that the timing of the reciprocation of the tool when machining the second surface is exactly 180⁰ from the first. Instead of producing each rotor in this manner, "copies" can be produced by molding or die casting after a "master" has been produced in the manner described. There is thus provided a rotor which maintains fluid-tight contact between the rotor and the sliders throughout the entire circumferential extent of the rotor. Thus the complex rotor vane contour desirable for good sealing of rounded nose sliders of the gate means can be created in a surprisingly simple manner.
In accordance with the second aspect of the invention, the efficiency of the pump is maintained by constructing the pump in such manner that worn parts can be easily, quickly and inexpensively replaced. The pump chamber is defined by complementary casing parts held in assembled relation solely by a shell into which they fit snugly. If parts become worn, they can be replaced merely by opening the shell, removing worn parts and replacing them by new or reconditioned parts. Moreover, the ease of disassembly of the pump makes it advantageous for use in industries such as the food industry where frequent disassembly for cleaning is required. A further factor contributing to long life and continued efficiency of the pump is the selection of materials. Thus, the rotor is preferably made of harder and more wear resistant material than the sliders and the casing parts which can easily be replaced. The ready replacement of parts has the further advantage that a pump can quickly be changed for other uses. For example when pumping low viscosity fluids, the casing parts defining the pump chamber are preferably made wholly or in part of elastomeric material of such hardness that it can be indented slightly by the crests of the undulations of the vane portion of the rotor thus in effect providing a tight seal by "negative clearance". The hardness may, for example, be 60 to 90 Durometer.
Preferably the casing parts in the hollow shell support axially projecting shaft portions of the rotor and the gate members of the gate means so as to permit accurate relative positioning of the interengaging parts of the rotor vane, the casing parts and the gate members and proper sealing.
In a further improvement, spaced elongate guide members are mounted, for example by fitting in a recess in the casing parts, on the casing parts on each side of the vane portion to hold the gate members slidably in between. A spring guide is provided with a spring with curved in ends to hold the gate members sealingly against the rotor vane in the course of reciprocation of the gate means. Preferably then openings are provided in one of the guide members to provide communication between the spaces at the rear of the gate members and the discharge chamber defined by the casing parts and the shell to facilitate movement of the gate members and help them to follow the vane undulations.
Further sealing efficiency benefits can be obtained by using elastomeric material to engage the vane portion and by spacing the end walls of the transport zone so that the vane crests indent the elastomeric material.

DRAWINGS:

Figure 1 is a perspective view of a pump in accordance with the invention, portions being broken away to show interior construction;
Figure 2 is an exploded perspective view of partially disassembled pump without the outer housing or shell;
Figure 3 is a vertical longitudinal section of the pump;
Figure 4 is a vertical cross section taken approximately on the line 4-4 in Figure 3;
Figure 5 is a side view of the rotor with adjacent shaft portions;
Figure 6 is a further side view of the rotor turned 90° from the position shown in Figure 5;
Figure 7 is a front view of the rotor shown in Figure 5;
Figure 8 is a schematic developed view of the pump chamber, rotor and sliders shown in a position in which the sliders engage a crest of the undulating vane portion of the rotor;
Figure 9 is a similar schematic developed view in which, however, the rotor is displacedλ/4;
Figure 10 is a similar schematic developed view but with the rotor displaced λ/2;
Figure 11 is a similar schematic developed view but with the rotor displaced 3X/4;
Figure 12 is a longitudinal section of another embodiment of the invention;
Figure 13 is a top plan view of the pump shown in Figure 12 with half of the outer shell or housing removed and with portions shown-in section;
Figure 14 is a cross section taken approximately on the line 14-14 in Figure 12;
Figure 15 is a schematic fragmentary view showing two sliders in two different positions with respect to a portion of the undulating vane of the rotor;
Figure 16 is a nose view of one of the sliders showing different lines of contact with the rotor;
Figures 17A and 17B are shematic views illustrating generation of the contour of surfaces of the rotor by means of milling cutters;
Figure 18 is a schematic longitudinal section of a pump in accordance with the invention showing certain parameters of an equation defining the rotor surface configuration.

Particular Description of Example of Invention

In Figures 1 to 11 of the drawings there is shown a first pump 20 having an outer shell or housing 21 with an inlet 22 and outlet 23. A pump chamber 24 having a suction chamber 25, transport zone 26 and discharge chamber 27 is formed in the housing. A rotor 28 is rotatable in the housing. The rotor has a hub 29 and a radially projecting vane or pump element 30. Sealing sliders 31 are provided between the suction chamber 25 and the discharge chamber 27.
The housing 21 comprises an annular cylindrical housing mantle 33 and two housing covers 34.1 and 34.2 which are set at the ends of the housing mantle 33 and are secured thereto in a manner not otherwise shown. Centering pins 32 are indicated. A cylindrical inlet nipple 35 for the inlet 22 and a cylindrical outlet nipple 36 in an upper region of the housing mantle are provided with threads 35.1 and 36.1 for connection of intake and discharge conduits. They have a cylindrical inlet bore 35.2 and a cylindrical outlet bore 36.2 respectively. These are midway between the ends of the housing mantle 33 and have corresponding openings in the housing wall which open into the suction chamber 25 and the discharge chamber 27. The suction chamber 25 and the inlet 22 represent the suction side and the discharge chamber 27 and outlet 23 represent the pressure side of the pump.
The housing cover 34.1 has a central bore 34.5 to receive a drive shaft. This central bore 34.5 is surrounded inwardly by a bearing shoulder 41 which is formed in the housing cover 34.1 and in its upper region merges into slider guides 42.1 and 42.2 which between them define the slider slot 43 which opens downwardly into the bearing bore 44. These parts are made of metal, for example stainless steel or brass. The housing cover 34.2 is basically similar but advantageously is formed integrally with the housing mantle 34 or is permantely secured to it by welding or otherwise. It requires no central bore 34.5 for reception of a drive shaft but can, however, have a recess closed by a cover which is not further represented. Also, it carries a bearing shoulder 41 which merges into the slider guides 42.
In the bearing shoulders 41, the rotor 28 is supported by bearing ends 29.1 and 29.2 of the hub 29, which, with a corresponding slide bearing fit, are therein rotatably supported and, if necessary, can be formed with bearing bushings or the like. Surrounding the bearing holders 41 up to about the pump axis 45 are inserted interchangeable casing parts 46.1 and 46.2 of a suitable plastic or rubber material, conveniently possessing a degree of resilience. These are formed outwardly with a surface 47 fitting in the housing mantle 33 and extend up to a surface 48 which defines the suction chamber 25 and the discharge chamber 27. Each interchangeable casing part 46.1 or 46.2 exends to a central plane 49 which is shown in Figure 3 where they abut. There the two parts divide. They are inserted in mirror image fashion permitting special production and assembly advantages. Together they define the pump chamber 24 through end faces 50.1 and ₅0.2 which are spaced equally from the central plane 49 and are disposed parallel to one another and define the transport zone 26 of the pump chamber 24. Their upper end edges 51 lie in a plane spaced above the pump axis 45 as seen in particular in Figure 4. The end edge 51 for reasons of production and symmetry is offset parallel to the diameter although it can also be radial. It must in any case throughout its entire length run slightly above the diameter of the housing in order to assure proper sealing. As clearly seen in Figure 2, it ends in an inclined face 52 which provides a transition to the surface 48 and makes easy production of the plastic or metal part 46.1 or 46.2 possible. Joining the pump channel end face 50 is a ring part 54 which surrounds the transport zone 26 and is formed integrally with the interchangeable part 46. As shown in Figure 2 it extends slightly above the end edges 51 in the end surface 55 and forms or limits the cylindrical inner circumferential surface 56 of the transport zone 26 of the pump channel ₂4. As the interchangeable part 46 is formed of a suitable plastic material there are provided good, low friction, slightly elastic surface.
The rotor 28 with the hub 29 and the bearing ends 29.1 and 29.2 carries in the middle a radially projecting pump element 30 surrounding the hub 29. This informed as a shaped element with wave form boundary surfaces. It comprises a thin sinusoidal vane or web projecting radially from the hub. It has an outer circumference 61 which is cylindrical and exactly conforms to the inner surface 56 of part 47 on which it slides. The contoured surfaces 60 on opposite sides of the pump element 30 are spaced from one another and are so formed that the outer circumferential surface 61 is a sinusoidal band. Both of the contoured surfaces 60 in their development are formed as a sine function in which the amplitude 63, as best seen in Figure 6, is the same at all distances from the axis of rotation of the rotor. As the circumferences increase with the outwardly increasing diameters, the sinusoidal curve continually becomes flatter radially outward. Such a pump element can be produced by computerized profile milling or profile planning or by casting. The pump element, on account of its favorable form, requires only few moving sealing parts since its inner circumference is fixed on the hub 29 and its outer circumferential surface 61 slidabjy engages the surface 56 in the pump channel 24; thus only its boundary surfaces 60 require sealing.
For sealing the boundary surfaces 60, there are provided sealing sliders 31 between the inlet and outlet and pump chamber end faces 50 in the transport region 26. The latter are, for example, plane faces perpendicular to the pump axis 45 the spacing of which is determined by the width of the inner circumferential surface 56 of the ring part 54 which corresponds exactly to the spacing 66 of the highest portion 65 of the boundary surfaces 60 on opposite sides of the pump element 30 as clearly seen in Figures 5 and 6 so that the crest lines of the sinusoidal form curved surfaces lie as straight sealing edges on the pump channel end faces 50.1 and 50.2 and thereby provide a seal as is described further below. The noses of the sliders are arcuate in cross section and the genetrices of the boundary surfaces are cylinders having the same radius as the noses of the sliders. The pump channel end faces 50.1 and 50.2 have a circumferential extent somewhat more than 180° so that with the selected number of two wavelengths in one circumference, the two highest portions 65 on one side of the pump element 30, when one has just left the suction chamber 25 and the other is shortly before the entrance in the discharge chamber 27, are approximately on the horizontal diameter and consequently fully seal and limit the enclosed volume.
For sealing the regions not in contact with the pump channel end surfaces 50 between the suction chamber 25 and the discharge chamber 27, sealing sliders 31 are provided. These are basically in the form of parallelapiped elements as can be seen from Figure 1. They have side bearing and sliding faces 70, an upper face 71 of which the radius corresponds to the outer circumferential surfaces 61, an under sliding surface 72 with a radius corresponding to that of hub 29, and inclined faces 74 ending in an arcuate sealing edge or rounded nose 73, and a stepped back surface 75. With the side sliding slider slot 43 and fits the slide surface 77 of the slider holder 42. The lower slide surface ₇2 has a sealing engagement with the hub 29 or the bearing ends 29.1, 29.2. As seen in Figures 1 and 2, the slide holders 42 are higher than the outer circumferential surface 61 of the pump element 30 by the thickness of the ring part 54. This intermediate space is to be bridged over. For this purpose there is provided an elongate insert part or spring guide 80 which has width of the slider slot 53 and a total length which approximately corresponds to the total length of the two sealing sliders 31 plus the thickness of the pump element 30. It has, in the middle, a connected web 81 and at the top an elongate recess 82 with two through-openings 83. Through these extend the spring ends 84 of a bow spring 85 which works in the manner of a leaf spring as a pressure-exerting tension spring with the spring ends 84 engaged in recesses 86 in the profiled back surfaces 75 of the sealing sliders 31. A projection 87 is, if necessary, provided on the sliders 31 as an additional stroke limiting device.
In each of the slider holders 42, a through opening 88 leads from the discharge chamber 27 to the slider slot 43 rearwardly of the slider so that the medium being pumped, presses on the sealing slider 31 from behind and thereby presses its sealing edge 73 against the boundary surface 60. The action of the spring 85, which presses the two sliders 31 against the boundary surfaces 60 of the rotor to compensate for wear and to provide good sealing, is thus reinforced. Moreover, the opening 88 provides for the escape of fluid when the slider is moved rearwardly, i.e. away from the central plane of the rotor, and thereby avoids the build-up of excessive pressure in the space behind the slider.
The form of the pump element 30 with the two boundary surfaces 60 is seen clearly from Figures 1 to 3. Moreover, in Figures 5 to 7, in which only the rotor 28 with the hub 29 and portions of the bearing ends 29.1 and 29.2 are shown, the pump element 30 on hub is seen in three different views. In particular from Figure 6 it is seen that the boundary surfaces 60 at the outer circumference Ua are essentially flatter than at the inner circumference Ui where they have the steepest contour. As the sine function, contrary to usual plane representation, deviates from circle to circle, there results a surface form which is difficult to represent in which the ordinate which corresponds to the stroke 63 of the boundary surface 60 or of the sliders 31 remains the same over the entire radius of the boundary surface and must remain the same for the rigid sealing slider 31 and the abscissa of the angle function varies according to the radius from the smallest circumference Ui to the largest circumference Ua, becoming continually larger and the surface hence flatter. The steepest curve region occurs at the inner circumference Ui and the steepest portion 67 is seen in the middle of Figure 6. The trace of the curve is determined through selection of the diameters and thereby the circumferences and the number of waves, so that taking into account the coefficient of friction of the material of the pump element 30 and the sealing slider 31 or the sealing edge, and the medium to be pumped, no self-locking occurs which would subject the slider to strong side forces. As will be seen, there are two wave lengths provided in the circumference whereby there are provided two highest positions 65.1, 65.2, 65.3 and 65.4 on each side of the pump element which are opposite the deepest portion 67 of the other boundary surface. The sealing edges 73 are rounded and the curved faces of the pump element are ground or machined as described below in order to obtain proper sealing relationship.
Figures 8 to 10 are schematic developed views showing the general operation of the pump. The views are taken approximately in the middle of the boundary surfaces ₆₀ between the inner circumference Ui and outer circumference Ua of the pump element 30. It is also shown how, through the through-hole 88, the pressure in the outlet A or 27 applies pressure behind the sealing slider 31 in the slider slot 43 to press the sealing slider against the boundary surfaces 60.
It is also seen from Figures 8 - to 10 how, through movement of the pump element 30 in the direction of the arrow 78 the chambers on both sides of the pump element 30 are successively filled and emptied. The chambers bounded by the boundary surfaces 60 are designated by letters E and A in order to show which regions are in communication with the suction chamber 25 or inlet 22/E and which regions are in conection with the discharge chamber 27 or outlet 23/A. The letter V designates the chamber between the boundary surfaces 60 and the pump channel end faces 50 in the condition in which the two highest positions 65 seal directly on both sides of the respective pump channel end surfaces 50 and thereby transport a separate enclosed volume of medium without further filling or emptying from the inlet to the outlet. This condition exists only so long as a crest of the rotor is in the rotary position between the horizontal diameter and the upper end edge 51. In all other condtions, as will be seen, the chambers on both sides of the pump element 30 are connected either with the inlet chamber E or the outler chamber A.
As the outer circumferential surface 61 is in sealing engagement with the inner circumferential surface 56 and the chamber is limited inwardly by the hub 29, there is no connection in an intermediate position between the outlet and inlet. On the other hand, through favorable profiling, unnecessary travel is avoided. As seen in Figures 8 to 11, the inlet and outlet regions take almost half a wave length with only a narrow overlap 79 for sealing, since the edge 51 lies somewhat above the horizontal diameter as shown in Figures 2 and 4. The edge 51 is schematically indicated in Figures 8 to 11 and respresents the limit of inlet E or outlet A and thereby the sealing edge or guiding edge for confining the respective closed transport volume V. As it is offset parallel to the diameter and the highest positions 65 and exactly radial, the opening of the enclosed volume V in the transport zone takes place first during the sweep of the overlap 79 and an initial very small triangular opening and then gradually enlarges whereby pressure qualization occurs without an appreciable shock. As seen in Figures 8 to 11, it is significant that the inlet and outlet lie respectively on both sides of the pump element 30 and also with both sides constantly connected. However, as the pump element 30 is a wave form collar-like part, the chamber on one side during rotation of the pump element continually increases or decreases while the chamber on the other side by a like volume decreases or increases. Hence there is a constant equal inflow and outflow of the medium being pumped. When the volume increment on one side becomes smallest and the medium passes over into the enclosed region V, the maximum possible amount flows on the other side and vice versa. Directly thereafter, the chamber V opens with limited flow to the outlet A/23/27 through which the medium flows with greatest volume out of the region A on the other side.
The operation of the pump is as follows:

The inlet 22 is connected to a suction line which is connected with or filled with the medium to be pumped. The outlet 23 is connected to a pressure hose which carries away the medium to be pumped. When the rotor is turned in the directionof the arrow 78 by a motor which engages a drive slot or recess 89 in the rotor, the rotor 28 with hub 29 and pump element 30 move toward the right in the schematic developed views of Figures 8 to 11. In Figure 8, the chamber El is just in the condition of maximum inflow while the chamber E2 is completely filled and henceforth moves in front of a surface area of the boundary surface 60 of the pump element without further filling until the highest position 65.2 reaches the upper end edge 51 and then the closed condition V prevails which, in Figure 10, also bear the designation (E2) in order to indicate which volume parts is here enclosed. In the meantime, chamber E3 is filled as seen in Figure 9, beginning slowly while the chamber El is filled with a limited volume part. Correspondingly, at the same time, the largest volume part will be pressed out of the chamber Al during a given period while the chamber A2 begins to partake in pressing out the medium with the smallest volume part in that period. It will be seen that as the volume part in each unit of time decreases in amount on one side, it increases on the other side. The sealing sliders 31 separate the inlet E from the outlet A and in front of them the medium is pressed into the outlet. The discharge pressure is applied through the openings 88 in the slider slot 43 and presses the sealing sliders 31 firmly against the boundary faces 60. Moreover, they are pressed toward one another by the bow spring 85 and consequently are pressed on the boundary faces 60. Through the sinusoidal movement of the boundary faces 60 and of the pump element 30, sealing sliders 31 are automatically moved back and fourth whereby they carry out a sinusoidal movement which leads to a progressive decrease and increase in velocity with limited acceleration in the end positions so that there is no danger of the sliders lifting off by reason of inertia.

There small sliding surfaces are easy to control and therefore permit pumping with limited losses. It can be driven at a low speed and also be used as a high speed pump according to the contruction, design, and the medium to be pumped. The pump is especially suitable for the food industry because it can be made of corrosion resisting material, for example bronze, stainless steel or plastic. Also, parts of the rotor or only the sealing faces can be made of suitable plastic or elastomeric material.
The sealing edges or the like on the sealing sliders 31 can be coated with a corresponding material or can be made of sintered or ceramic material. The pumps are therefore especially suitable for the food industry and for other media containing delicate components and thick material because there are no parts having a swinging or flapping movement which, together with other pump parts in most pumps, tend to crush and damage sensitive components of the medium being pumped. The pump is of simple construction with no valves and has only a single one-piece rotating part and with only one sealing slider on each side. The construction can be easily disassembled with replacement parts. The pump can have a high capacity and be of simple construction as well as be reliable in operation.
The sealing sliders 31 may be made wholly of plastic material. The sealing edges are rounded and the boundary faces 60 correspondingly corrected as described below. When better sealing between the inlet and outlet is desired, in particular to attain higher pressure, more than one slider, for example two or three sliders, can be arranged next to one another.
Also, more than two wave lengths can be provided in the circumference. Then, the volume part enclosed in the region V is transported over a greater distance and there can be more than one sealing part in the highest portions 65 for each wave length on the pump channel faces whereby loss through back flow is reduced.
In the illustrated embodiment the simplest theoretical form, namely a straight cylinder which is perpendicular to the pump axis 45, is used as the generatrix for the boundary srufaces. If need be, the cylinder may be modified to incline its outside wall, tapering it, or the generatrix can be given a suitable profile be selected according to the flow relationships and the requirements of the sealing slider form. Inlet and outlet regions and openings can be made larger or smaller according to the intended use of the pump. The embodiment described provides for the largest possible inlet and outlet cross section relative to the wave length which, without lost space and enlarging the pump dimensions, realizes optimal flow relationship and connection conditions. The cross section of the connections and the provisions for securing the conduits can be formed and profiled in different ways.
A further embodiment of the invention shown in Figures 12 to 14 comprises a pump 100 having a cylindrical outer shell or housing 101. At one end of the housing 101 there is a removable cover 102 secured to the housing by a plurality of stud bolts 103 only one such bolt and nut being shown in Figure 12. The cover 102 has an integral foot portion 102.1 by means of which the pump can be mounted on a suitable base or support (not shown).
A rear casing part 105 fits into a rear portion of the cylindrical housing 101 and a front casing part 106 fits into a forward portion of the housing and is secured by the cover 102. Sealing rings 107, for example O-rings provide fluid tight seals between the casing parts and the housing. Between the rear casing part 105 and front casing part 106 there are two casing liners 108, 109 which are held in position by circular bosses 108.1, 109.1 which fit in recesses provided in casing parts 105, 106 respectively. Since the housing 101, cover 102, casing parts 105, 106 and casing liners 108, 109 are made as separate parts, they can conveniently be of different materials. For example the housing 101 may be made of aluminium, steel, stainless steel, alloy or plastic. The cover 102 is conveniently made as a casting or molding for example of iron, aluminium or plastic. The rear casing part ₁05 and front casing part 106 can, for example, be made of aluminium, steel, stainless steel, alloy or plastic. The material of the casing liners 108.1, 109.1 is selected in accordance with the material of the rotor (described below) and the fluid which the pump is designed to handle. For example the casing liners may be made of rubber, elastomers, plastic, steel, stainless steel or bronze.
The complementary casing parts 105, 106 together with casing liners 108, 109 define a pump chamber 110 comprising a suction chamber 110.1, a discharge chamber 110.2 and a transport zone 110.3. The transport zone 110.3 defined by the casing liners 108, 109 has a cylindrical inner peripheral wall surface 110.4 and opposite planar end walls 110.5. The pump housing 101 is provided with an inlet 111 opening into the suction chamber 101.1 and an outlet 112 opening into the discharge chamber 110.2.
A pump rotor 113 rotable in the pump chamber comprises a central hub portion 113.1, an undulating vane portion 113.2 projecting radially from the hub and shaft portion 113.3 extending axially from opposite ends of the hub and rotatably received in bearing bushings 114 provided in the casing parts 105, 106. The rotor is coaxial with the inner peripheral surface 110.4 of the transport zone 110.3 and the outer periphery of the vane portion 113.2 of the rotor in fluid tight sliding contact with the inner periphery of the transport zone. opposite surfaces of the undulating vane portion 113.2 are smooth, continuous cyclic curves the crests of which are in fluid tight sliding contact with the opposite end walls 110.5 of the transport zone 110.3. As in the case of the rotor illustrated in schematic developed views in Figures 10 to 11, there are at least two complete cycles in the circumferential extent of the rotor so that two crests facing in one direction and slidably engageable with one end wall of the transport zone 110.3 alternate with two crests facing in the opposite direction and slidably engageable with the opposite end wall of the transport zone.
Between the suction chamber 110.1 and discharge chamber 110.2 there is provided a gate assembly comprising two sliders or gate members 116 slidable in a direction parallel to the axis of the rotor between two longitudinally extending guide members 116, 117 which are received in, and held in position by, recesses in the casing parts 105, 106 and bushings 114 (Figure 14). The guide members 116, 117 have a width in a direction radial of the rotor somewhat greater than the radial extent of the vane portion 113.2 and are notched to provide passage for the rotor vane portion (Figure 12). The sliders 115 have a width in a radial direction of the rotor equal to the radial extent of the vane portion 113.2. As will be described more fully below, the sliders 115 have rounded noses 115.1 engageable respectively with opposite sides of the vane portion 113.2 of the rotor and are urged toward the rotor by a bow spring 118 having curved end portions fitted into recesses in the rear ends of the sliders 115. The spring 118 is guidable by an elongate spring guide 119 which fits into elongate recesses in radial outer portions of the spring guides 116, 117 and is provided with a longitudinal recess in which the spring 118 is received and guided (Figure 14). The inner face of the spring guide 119 is in sliding contact with the outer periphery of the vane portion 113.2 of the rotor.
It will be understood that by reason of engagement of the sliders with the undulating surfaces of 113.2 of the rotor, a reciprocatory motion will be imparted to the sliders as the rotor rotates. The spring 118 reciprocates with the sliders and continually urges them toward the vane portion of the rotor so as to maintain fluid tight contact therewith. The rotor is so designed, as will be described more fully below, so that the spacing between the sliders remains substantially constant. As the two sliders thus move with one another, the spring 118 is not flexed by reciprocation of the sliders but serves to overcome frictional, fluid and inertial forces and to compensate for wear.
As the sliders 115 sliding between the guide members 116, 117 act in effect as piston pumps with respect to any fluid behind them, the guide member 117 on the side of the discharge chamber is provided with openings 117.1 (Figure 12) which open into recesses 120 (Figure 14) in casing parts 105, 106 to provide for the ready escape to the discharge chamber of fluid in the space between the guide members 116, 117 behind the sliders 115.
The material of the rotor, sliders, guide members and spring guide are selected to provide- long and trouble-free operation of the pump. As the rotor is more complex in its configuration than the sliders, the rotor is preferably made of hard, wear-resisting material such as cast steel, stainless steel, alloy or plastic. The material of the sliders 115 is selected so as to minimize wear on the rotor. They may, for example, be formed of carbon, plastic, ceramic or bronze. The material of the spring guide 119 is selected to minimize wear on the rotor whose periphery it engages. It may, for example, be cast iron, steel, stainless steel, alloy, plastic, carbon or bronze. The material of the spring is carefully selected so as to maintain the sliders in proper contact with the vane portion of the rotor and also maintain the spring guide 119 in contact with the periphery of the rotor. The spring may for example be formed of cast steel, stainless steel, alloy or bronze.
The rotor is driven in rotation by means of a drive shaft 121 rotatably supported in axial alignment with the rotor by bearings 122 in a projecting portion 102.2 of the cover 102. A fluid tight seal 123 is provided around the drive shaft where it passes through the cover. At the inner end of the drive shaft there is provided a torque-transmitting connection 124 between the drive shaft and one of the shaft portions of the rotor. This is shown by way of example as a flat end on the drive shaft received in a transverse slot in the rotor shaft.
From the drawings and the foregoing description it will be understood that the pump can be disassembled and reassembled easily and quickly. When the nuts 104 are unscrewed, the cover 102 together with the drive shaft 121 can be removed. All of the inner parts of the pump will then slip out of the open end of the housing and will thereupon come apart since they are held together by the housing. This has important advantages. The individual parts can be inspected and worn parts replaced. Thus for example if, by reason of wear, a clearance has developed between the rotor and the casing liners defining the transport zone of the pump chamber, these parts can be replaced so that the pump is again "tight". Moreover by replacing parts with corresponding parts of different material the pump can be converted from one type of service to another. For example metallic casing liners 108, 109 can be replaced by casing liners of an elastic material such as rubber or an elastomer of such dimensions as to provide "negative clearance" with respect to the rotor for pumping low viscosity fluids. When for sanitary or other reasons it is desirable to clean the pump this can be done easily and quickly by reason of the construction of the pump.
Although the pump is simple in overall design the configuration of the undulating vane portion of the rotor is more complex than has heretofore be recognized. This is believed to account for the fact that pumps of this kind have not come into use although they have been proposed more than 100 years ago. While it might be assumed that the vane portion of the rotor could and should be of uniform thickness throughout, this is not the case. Since the angle at which the vane passes between the sliders is continually changing and also varies with the radial distance from the axis and thickness of the vane must be varied in order to maintain a constant spacing of the sliders from one another. This is illustrated schematically in Figure 15 where it will be seen that the portion of the slider at position A is thinner than the portion at position B although the spacing between the sliders is the same. Whereas Figure 15 illustrates the vane of the rotor at only one radial distance from the axis, it will be understood that the slope of the vane with reference to a central plane increases as the distance from the axis of rotation decreases.
Moreover a further complexity is introduced by reason of the nose of the slider being rounded.
As will be seen in Figure 15 the vane engages the noses of the sliders along their centre lines in position B. However, at position A the vane portion of the rotor engages side portions of the noses of the slider. Moreover, the line along which the vane portion of he rotor engages the slider varies in a radial direction.
This is illustrated in Figure 16 which shows different contact lines.
At the crests of the undulations, the line of contact between the rotor and slider is a straight line which is radial and perpendicular to the axis of the rotor. At all other positions, the contact line is continually varying. It not only is not perpendicular to the axis of the rotor but moreover is not a straight line but rather a three dimensional curve.
By reasons of this the radius of curvature of the nose portions of the sliders is a factor that must be taken into account in determining the varying thickness of the vane portion of the rotor.
For example in a two inch pump having the following parameters (assuming the curve is a sine curve):
then:

where:

D is the diameter at specified point,
0 is the angle of vane to the sliders as illustrated in Figure 18
a is the rotor rotations angle x 2 The following values are obtained:

Assuming that the wave form of the undulations of the vane portion of the rotor is a sine curve and that there are two wave lengths in the circumference of the rotor the contour of the opposite surface,s of the vane is a function of the angle of rotation of the rotor, the distance of each point from the axis, the amplitude of the wave (distance between walls of pump chamber - thickness of vane at crests) and the radius of the nose of the sliders. The contour can be produced by a computerized milling machine or profiler which is programmed in accordance with these functions. However, a simple and practical mode of manufacturing the rotor is to mold or cast it to approximate shape and then finish opposite surfaces of the rotor vane by means of a milling cutter or other tool which has a radius equal to the radius of the nose of the sliders. The rotor is mounted on the arbor of the milling machine whereby it can be rotated slowly. The cutting tool is mounted in the machine in a position perpendicular to the axis of the rotor and is reciprocated in an axial direction (while rotating about its own axis) so as to make two complete strokes per revolution of the rotor. The length of each stroke is equal to the amplitude of the wave form to be produced. A correct surface taking into account the radius of curvature of the nose of the slider is thereby produced.
If the milling machine is capable of using two milling cutters suitably spaced from one another both surfaces of the vane can be generated at the same time. This is illustrated schematically in Figures 17A and 17B where a portion of the vane of a rotor is designated _V and the cutters shown in different positions with respect to the vane are designated C. Figure 17A represents a portion of the vane at its outer periphery while Figure 17B represents an inner portion of the vane where it will be seen that the slope is steeper. If the milling machine is not capable of operating two cutters simultaneously, the opposite surfaces of the vane can be finished individually, care being taken that the two surfaces are properly oriented with respect to one another.
It will be understood tht when a plurality of like pumps is being produced, it is not necessary to machine each rotor in the manner described. When one rotor has been produced in this manner it can be used as a master for producing duplicates, for example, by molding or die-casting or by a copying profiler. The cost of production can thereby be reduced.

Claims

1. A rotary fluid pump having a hollow shell with two separable parts and means for securing the parts together, a pump chamber with a suction chamber, a discharge chamber and transport zone extending circumferentially between the suction chamber and the discharge chamber, a rotor rotatably received in the pump chamber with a hub portion and an undulating vane portion projecting radially outwards from the hub portion and having an outer periphery slidably engaging an inner peripheral surface of the transport zone of the pump chamber and opposite surfaces which in a circumferential direction are continuous cyclic curves with at least two complete cycles, crests of the curves slidably engaging opposite planar end surfaces of the pump chamber, gate means separating the suction and discharge chambers with rounded nose portions springingly engaging opposite faces of the vane member, and inlet and outlet openings communicating respectively with the suction and discharge chamber characterised in that
the vane portion (30; 113.2) has a thickness (T) which varies in a circumferential direction in differently inclined vane parts and varies in a radial direction in the inclined vane parts to provide line contact with the rounded nose portions (73;115.1) throughout the radial extent of the vane portion (30; 113.2) during a full revolution of the rotor (28; 113).

2. A rotary fluid pump according to claim 1 further characterised in that the nose portions (30; 113.2) are arcuate with a predetermined radius (R) in a section parallel to axis of rotor rotation and in that the opposite surfaces (60) of the vane portion (30; 113.2) are surfaces with a contour which would be generated by rotary cutters rotatable about axes perpendicular to the axis of rotation of the rotor (28; 113) having a radius equal to the radius (R) of curvature of the nose portions (73; 115.1) and reciprocated cyclically in a direction axial of the rotor (28; 113) in phased relation to the angular rotor position (a).

3. A rotary fluid pump according to claim 1 or claim 2 further characterised in that casing parts (46.1, 46.2; 105, 106, 108, 109) received in the hollow shell (21; 101) rotatably support axially projecting shaft portions (29.1; 29.2; 113.3), one of the shaft portions having means (98; 124) for driving the rotor (28; 113) and slidably support gate members (31; 115) having the rounded nose portions (73; 115.1), the casing parts (46.1; 46.2; 105, 106) having end faces (50.1; 50.2; 110.5) defining the circumferentially extending transport zone (26; 110.3) and being in sealing proximity with the vane portion (30; 113.2).

4. A rotary fluid pump according to claim 3 further characterised in that two elongate guide members (42.1, 42.2; 116, 117) are mounted on the casing parts (46.1, 46.2; 105, 106, 108, 109) on each side of the vane portion (30; 113.2) spaced apart to support the gate members (31; 115) therebetween and support a spring guide (80; 119) in sealing proximity to an outer cylindrical face (61, 113.2) of the vane portion (30; 113.2) and in that a leaf spring (85; 118) having curved in ends (84) is located in the guide (80; 119) and engages the respective gate members (31; 115) to hold them in sealing engagement with the vane portion (30; 113.2).

5. A rotary fluid pump accoding to claim 4 further characterised in that openings (88; 117.1) are provided in one of the guide members (42.1, 42.2; 116, 117) to provide communication between the discharge chamber (27; 110.2) defined by the casing parts (46.1, 46.2; 105, 106, 108, 109) and the shell (21; 101) and a space between the guide members (42.1, 42.2; 116; 117) and the gate members (31; 115).

6. A rotary fluid pump according to claim 4 or claim 5 further characterised in that the spring guide (80; 119) is fixed non-movably between the shell (21; 101) and the gate members (31; 115) and has slots (82, 83) for permitting reciprocation of the in-curved ends (84).

7. A rotary fluid pump according to any of claims 3 to 6 further characterised in that at least portions (46.1, 46.2; 108, 109) of the casing parts defining the transport zone (26; 110.3) in sealing proximity with the vane portion (30; 113.2) are of elastomeric material.

8. A rotary fluid pump according to claim 7 further characterised in that the distance between the end faces (50.1, 50.2; 110.5) is less than the maximum axial dimension of the vane portion (30; 113.2) to enhance sealing by the crests of the vane portion (30; 113.2) indenting the end face (50.1, 50.2; 110.5.

9. A rotary fluid pump according to any of claims 3 to 8 further characterised in that the hollow shell (21; 101) includes a cylindrical portion (33; 101) open at an end, a closure (34.1 or 34.2; 102) securable at that end, the casing parts (46.1, 46.2; 105, 106, 108, 109), rotor (28; 113) and gate means (31; 115) being removably insertable into the cylindrical portion (33; 101) to be retained therein on securing the closure (34.1 or 34.2; 102) to hold them into suitable mutually sealing assembled relation.

10. A rotary fluid pump according to claim 9 further characterised in that a drive shaft (121) for the rotor (113) extends through and is rotatably supported by the closure (102) in axial alignment with the axially projecting shaft portions (113.3) carried in bearings (114) carried in the casing parts (105, 106, 108, 109) held in assembled relationship inside the shell (101).

11. A rotary fluid pump having a hollow shell with two separable parts and means for securing the parts together, a pump chamber with a suction chamber, a discharge chamber and a transport zone extending circumferentially between the suction chamber and the discharge chamber, a rotor rotatably received in the pump chamber with a hub portion and undulating vane portion projecting radially outwards from the hub portion and having an outer periphery slidably engaging an inner peripheral surface of the transport zone of the pump chamber and opposite surfaces which in a circumferential direction are continuous cyclic curves' with at least two complete cycles, crests of the curves slidably engaging opposite planar end surfaces of the pump chamber, gate means separating the suction and discharge chambers with rounded nose portions springingly engaging opposite faces of the vane member, and inlet and outlet openings communicating respectively with the suction and discharge chamber characterised in that complementary casing parts (46.1, 46.2; 105, 106, 108, 109) are removably insertable in the hollow shell (21; 101) with cylindrical inner surfaces (56; 110.4),and opposite planar end faces (50.1, 50.2; 110.5) defining the transport zone (26; 110.3) of a circumferential extent sufficient to engage a pair of crests of the vane portion (30; 113.2) of the rotor (28; 113) received in the transport zone (26; 110.3), the casing parts supporting, internally of the shell, removably insertable elongate guide members (42.1, 42.2; 116, 117) for slidably supporting gate members (31; 115) for reciprocable axial movement inside the shell to separate the suction chamber (25; 110.2) and discharge chamber (27; 110.2) defined above the said casing parts.

12. A rotary fluid pump according to claim 11 further characterised in that a spring guide (80; 119) is removably insertable between spaced apart guide members (42.1, 42.2; 116, 117) on each side of the vane portion (30; 113.2) and the shell (21, 101) for location in sealing proximity to an outer cylindrical face (61, 113.2) of the vane portion (30; 113.2), a leaf spring (85; 118) having curved-in ends (84) is slidably located in the spring guide (80; 119) to engage the gate members (31; 115) and urge them in sealing engagement with the vane portion (30; 113.2).

13. A rotary fluid pump according to claim 12 further characterised in that openings (88; 117.1) are provided in one of the guide members (42.1, 42.2; 116, 117) to provide communication between the discharge chamber (27; 110.2) defined by the casing parts (46.1, 46.2; 105, 106, 108, 109) and the shell (21; 101) and a space between the guide members (42.1, 42.2; 116; 117) and the gate members (31; 115).

14. A rotary fluid pump according to claim 11 or claim 12 further characterised in that the hollow shell (21; 101) includes a cylindrical (33; 101) portion open at an end, a closure (34.1 or 34.2; 102) securable at that end, the casing parts (46.1, 46.2; 105, 106, 108, 109) rotor (28; 113) and gate means (31; 115) being removably insertable into the cylindrical portion (33; 101) to be retained therein on securing the closure (34.1 or 34.2; 102) to hold them into suitable mutually sealing assembled relation.

15. A rotary fluid pump according to any of the preceding claims further characterised in that the outer periphery (61; 113.2) of the vane portion (30; 113.2) is spaced from the shell (21; 101) in the suction and discharge chambers (25, 27; 110.1., 110.2) to permit constant fluid flow between the parts of the chambers on either side of the rotor vane portion (30; 113.2).